DE2028908C3 - Four-wire subscriber circuit and four-wire subscriber station - Google Patents

Description

028

designated. At this Spraehsammelsehiene SS lieuen si) many sample sample receivers and senders, such as participants are present. Only one of these amplitude sample receivers and probes is shown, namely APE and APS. The amplitude sample transmitter and receiver are controlled via the .SZ line. by a connecting string not shown in the drawing. An amplifier V I is connected to the amplitude prohen receiver APE , which amplifier amplifies the demodulated signal and which in turn is connected to the winding WS of the fork Gl and to the switching amplifier SV . The switching amplifier SV is used to control the switching relay SR, the contacts of which are labeled rl and rl and which has the task of switching on the ringing current for the alarm clock. A connection leads from the amplitude sample transmitter APS via the capacitor C 1 to the winding W 6 of the fork Eq. A resistor R 1 is connected in parallel with the winding W 6 and is used for ao adaptation to the amplitude sample end of the APS . A simulation resistor / V is provided for simulating the line voltage, which is placed in a known manner between the windings W 1 and W2 of the fork G 1. The windings W 2 and WA of the fork Gl are connected to one another via a capacitor C 2. The end of the winding W 2 facing away from the capacitor Γ 2, that is to say the ij line, is also connected to a further capacitor C 3, a feed choke Dft 1 and a filter F 1. While the feed choke DR 1 is connected to a DC voltage source via the loop status detector Ea , the capacitor forms a connection between the "line" and the / "line. The mentioned filter Fl consists of the two inductances Ll, L 2 and the capacitors C 4, C 5, C 6. A second feed choke DR 2 is connected to the dr fe line and with its end facing away from the b line with Eb and connected via a capacitor Cl to the Speisedro ^ sel DR. 1

A line M coming from a status scanner (not shown) leads to separate inputs of Ea and Eb.

The subscriber station corresponds in all respects to the conventional circuit; In the usual way, a loudspeaker LS is coupled to a microphone MN via a hybrid circuit. Between the a- and b-line there is the number switch working contact nsa on the one hand and the series connection of the alarm clock W with a capacitor C 8 on the other hand.

The number switch normally open contact is connected to the capacitor C 8 via a parallel circuit of the number switch pulse concoction nsi and the series circuit of C9 and Al via the hook switch GU .

The mode of operation of the two-wire subscriber circuit should now be based on the various actuations of a participant.

Will a participant record with another subscriber one conversation, he first picks up the phone and thus operates the hook switch GU in the subscriber station II About the Schleifenzustandser ';. Enner Ea and Eb and on the Speisedrosscln DR 1 and DR 2 can now Loop current flow because a DC voltage of - 48 V is applied. The loop current is registered by the loop state recognizer Ea . The loop status detector Ii b responds only when an icon not shown in the drawing has been pressed.

The SehleüenziiMandserkenner then sends a signal via the marking line Λί to the status scanner (not shown) in the form of constant-voltage pulses. The signal that the subscriber hears on his loudspeaker is generally generated by a central sound modulator and passed on to the listener via the busbar and V 1. A conventional alarm clock can be used in the subscriber station, since the fork has been bypassed by the relay Λ. If the subscriber now dials a number, the loop current is interrupted in pulses by the number switch pulse contact nsi. The dialing pulses generated in this way pass via the switching amplifier SV to the amplitude sampling transmitter APS, which also enables a synchronizing signal to be transmitted to the speech melding rail SS.

After the wall! of the number Jcs calling subscriber, a central control unit processes the information supplied to it by the dialing register and gives a connection memory the command to establish a connection between the two subscribers. The connection memory establishes this connection by actuating the amplitude sample transmitter A PS of the calling subscriber at the same time as the amplitude sample receiver of the called subscriber (not shown here) via the control line .SL. The LF signal of the calling subscriber reaches the filter via the fork Gl and the ίΐ-6 connections. The FiItCrZ ⁷ I limits the frequency band to the CCITT range. On the one hand, it should keep the frequencies above half the sampling frequency coming from the subscriber station away from the amplitude sampling transmitter APS : on the other hand, it should keep the frequencies above half the sampling frequency coming from the amplitude sampling receiver away from the subscribing station and thereby recover the original function of the sienil from the rectangular voltage sequence.

The changed NF signal comes from the filter F1! to fork Gl. from which it is transferred back to four-wire operation. The signals emanating from the calling subscriber are therefore only fed to the amplitude sampling transmitter APS via the parallel connection of the resistor RA and the winding W 6 and the capacitor C1 connected in series with this parallel connection. The amplitude sample transmitter APS now takes amplitude samples from the LF signal in accordance with a clock rate emanating from the connection memory and sends them to the voice bus SS. The voice information from the call participant (not shown) sounds from the voice collector SS in the form of amplitude samples to the amplitude sample receiver APE. This switches the signals through so that they can be amplified by the amplifier V 1 and fed via the fork G 1 in two-wire form to the filter Fl, which restores the original waveform of the speech signal. The voice signal reaches the subscriber station from the filter F1 in a known manner.

In Fig. 2 it is shown which changes are made to the circuit diagram of FIG must to achieve four-wire operation. at

of the subscriber circuit, the windings W 1 and W 3 and the simulation resistor N have disappeared. This can be done e.g. D. can be achieved by mechanically separating the connections between the elements mentioned.

The DH 2 throttle is no longer on the b-Lcitting. but at the capacitor Cl, while the filter F 2 is connected in parallel with the winding WM. The filter / · '2 is the only newly added element; the other changes in the subscriber circuit consist exclusively of the dead of existing connections.

At the subscriber station, the loudspeaker is separated from the fork (H and connected directly to a matching transformer Vi) , which in turn is connected to the filter / · ¹ 2 via lines. A replication resistor RN is connected in parallel with the secondary winding W 9, which serves to compensate for the now changed electrical conditions at the microphone MN / u.

The mode of operation of this new circuit arrangement is as follows:

The signals emanating from the subscriber are transmitted as before to the windings W 2 and ΙΓ4 of the former fork d 1. There they are not passed through a fork, but through a transformer, consisting of the windings W1 and W6, to the amplitude test transmitter.

The signals picked up by the amplitude sampler receiver are also no longer passed via a fork, but via a transformer consisting of the windings WS and W 4. Since the filter F 1 has already been assigned for the signals emanating from the subscriber shown, the incoming signals must be fed to the filter F 2, which is otherwise constructed in the same way as the filter F1 . To adapt to the changed resistance conditions, the incoming LF signal is switched on directly to the loudspeaker LS via the transformer A Ü .

With the new circuit arrangement - which of course only makes sense if the associated Switching device a four-wire

to space- or time-multiplied through-coupling network has - is only a full Duplcx operation with Allows traffic. In addition, the switching on of hands-free devices as a result of the compared to lower feedback signals

facilitated double-wire operation.

1 sheet of drawings

Claims (3)

1 2 meldeaiilagen known in which the connection claims: circuits of the individual subscriber lines in cyclic sequence scanned one after the other and the 1. Circuit arrangement for the four-wire operation.szusiände on voltage values of a tap operation of a two-wire subscriber station with 5 can be recognized (German patents I 260 552, hybrid circuit and a two-wire subscriber 1 3ClO 076). These subscriber circuits are, however, circuit with hybrid circuit in fine signaling systems designed for two-wire voice transmission with time-division multiplex voice transmission, and initially not suitable for four-wire operation, in which the loop status detectors of the individual subscriber lines in a further known circuit arrangement in cyclical order io for a hybrid circuit, in particular for Sampled one after the other and the operating states multiplex switches (German Auslcgeschrift are recognized by the voltage values of a tap 1 297 164), the hybrid circuit is used to connect the and where the time-multiplexed speech of a two-wire line, with a four-wire line transmission by means of an amplitude sample transmitter for the two-wire or amplitude sample receiver, the subscriber circuit designed for the four is characterized by the fact that the winding wire operation is converted, but a special one en (Wl, Wl, W3, W4) of the hybrid circuit hybrid circuit specified, which also has (Gl) the subscriber circuit (I), including special buffers and switches, maintaining their original spatial position. Finally, it is also from the PCM-Iechni! are electrically separated from one another and only one arrangement is known which, with a very short part, still functions as a transformer winding, receiver lines fill a four-wire subscriber station and that provides for amplitude sampling; Otherwise, the transition from two-receiver (APE) associated winding (W 4) wire to four-wire within the concentrator ^ connected to a low-pass filter (F2) can be made (electrical communication system, which is transmitted via a matching transformer (AU) 35 vol. 3S, No. 1, 1963, pages 16/17). With this connection to the loudspeaker (LS) of the subscriber order, however, there is likewise no preset · .: station (II) is connected. Two-wire subscriber station or subscriber school 2. Circuit arrangement according to claim 1, converted to data for four-wire operation. characterized in that in the participant The invention is based on the object of a station (II) p-.rallel to the speaker-side 30 for the two-wire operation designed subscriber part of the fork (G 2) a simulation resistor circuit with simple means for the four-wire (RN) is provided. retrofitting operation. 3. Circuit arrangement according to claim 1, that this object is characterized according to the invention in that the solves in the ö-line that the windings of the hybrid circuit of the horizontal feed choke (D ^ 2) via a Kon- 35 subscriber circuit while maintaining their urdensator (C2) with the winding (W2) assigned to the spatial position of the amplitude sample, electrically from one another transmitter (APS) , which are separated and only have the function of a fork (Gl) connected. fulfill the carrier winding and that the amplitude sample receiver associated winding with a 40 low-pass filter is connected, which has a Adaptation transformer to the loudspeaker of the partial subscriber station is connected. In an advantageous embodiment of this invention is in the subscriber station parallel to the loud- 45 speaker-side part of the fork a replica The invention relates to a circuit arrangement provided resistor RN. for the four-wire operation of a two-wire part is also connected to the fc line subscriber station with hybrid circuit and a two-feed throttle via a capacitor with the wire subscriber circuit with hybrid circuit in the amplitude sample transmitter associated winding of the Telecommunication systems connected with time-division multiplexer voice over 50 fork. transmission, in which the loop state recognizer of the advantages achieved with the invention exist individual subscriber lines in a cyclical sequence in particular that if there are two one after the other scanned and the operating states of wiry subscriber stations and subscriber voltage values of a tap are recognized and only simple measures such as disconnection in which the time-multiplex voice transmission ⁵⁵ of connections and the addition of a few switching means amplitude sample transmitter or Amplitude parts, required to make a four-wire sample receiver done. . To achieve operation. In zitmultiplexen switching systems, in particular an embodiment of the invention is in the especially in the case of private branch exchanges, it is shown for reasons of drawing and is explained in more detail below the better data transfer desired, all 60 described. It shows To train circuit parts four-wire. However, since Fig. 1 is a two-wire subscriber circuit and in numerous cases already a two-wire partial a two-wire subscriber station for time division multiplexing subscriber circuit and a two-wire subscriber switching system, station are given, the question arises whether F i g. 2 one from the arrangement according to FIG. 1 her- and, if necessary, in what manner the previous four-wire subscriber station and an existing device can also be used for a four-wire subscriber circuit for time-division multiplexed wire operation. There are switching systems, already relayless subscriber circuits for remote In F i g. 1 is a voice bus with SS